Cavity Flow Instabilities in a Purged High-Pressure Turbine Stage

cavity modes; fast-response pressure measurements; high-pressure turbine; high-speed turbine; ingress–egress mechanisms; rim-seal instability; Cavity mode; Fast response; Fast-response pressure measurement; Flow instabilities; High pressure turbine; High-speed turbine; Ingress/egress; Ingress–egress mechanism; Rim seals; Rim-seal instability; Aerospace Engineering; Energy Engineering and Power Technology; Mechanical Engineering

Abstract :

[en] As designers push engine efficiency closer to thermodynamic limits, the analysis of flow instabilities developed in a high-pressure turbine (HPT) is crucial to minimizing aerodynamic losses and optimizing secondary air systems. Purge flow, while essential for protecting turbine components from thermal stress, significantly impacts the overall efficiency of the engine and is strictly connected to cavity modes and rim-seal instabilities. This paper presents an experimental investigation of these instabilities in an HPT stage, tested under engine-representative flow conditions in the short-duration turbine rig of the von Karman Institute. As operating conditions significantly influence instability behavior, this study provides valuable insight for future turbine design. Fast-response pressure measurements reveal asynchronous flow instabilities linked to ingress–egress mechanisms, with intensities modulated by the purge rate (PR). The maximum strength is reached at PR = 1.0%, with comparable intensities persisting for higher rates. For lower PRs, the instability diminishes as the cavity becomes unsealed. An analysis based on the cross-power spectral density is applied to quantify the characteristics of the rotating instabilities. The speed of the asynchronous structures exhibits minimal sensitivity to the PR, approximately 65% of the rotor speed. In contrast, the structures’ length scale shows considerable variation, ranging from 11–12 lobes at PR = 1.0% to 14 lobes for PR = 1.74%. The frequency domain analysis reveals a complex modulation of these instabilities and suggests a potential correlation with low-engine-order fluctuations.

Disciplines :

Aerospace & aeronautics engineering

Author, co-author :

Da Valle, Lorenzo ; Université de Liège - ULiège > Faculté des Sciences Appliquées > Doct. sc. ingé. tech. (aérospat. méca.) ; Université de Liège - ULiège > Faculté des Sciences Appliquées > Form. doct. sc. ingé. & techno. (aéro. & mécan. - Paysage) ; Turbomachinery and Propulsion Department, von Kàrmàn Institute for Fluid Dynamics, Rhode-St-Genèse, Belgium

Cernat, Bogdan Cezar ; Turbomachinery and Propulsion Department, von Kàrmàn Institute for Fluid Dynamics, Rhode-St-Genèse, Belgium

Lavagnoli, Sergio ; Turbomachinery and Propulsion Department, von Kàrmàn Institute for Fluid Dynamics, Rhode-St-Genèse, Belgium

Language :

English

Title :

Cavity Flow Instabilities in a Purged High-Pressure Turbine Stage

Publication date :

September 2025

Journal title :

International Journal of Turbomachinery, Propulsion and Power

eISSN :

2504-186X

Publisher :

Multidisciplinary Digital Publishing Institute (MDPI)

Volume :

Issue :

Pages :

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://www.mdpi.com/2504-186X/10/3/15/pdf

Funders :

VKI - Von Karman Institute for Fluid Dynamics
Safran - Safran Tech

Funding text :

This research was funded by the von Karman Institute for Fluid Dynamics and Safran Aircraft Engines.

Available on ORBi :

since 25 November 2025

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